Mitigation of external fields in piezoelectric sensors

ABSTRACT

An apparatus ( 22 ) for processing signals from a touch panel ( 10 ) is described. The touch panel ( 10 ) includes a layer of piezoelectric material ( 16 ) disposed between a plurality of sensing electrodes ( 14, 20 ) and at least one common electrode ( 15 ). The apparatus ( 22 ) includes a first circuit ( 23 ) for connection to the plurality of sensing electrodes ( 14, 20 ). The first circuit ( 23 ) is configured to generate a plurality of first pressure signals ( 29 ). Each first pressure signal ( 29 ) corresponds to one or more sensing electrodes ( 14, 20 ) and is indicative of a pressure acting on the touch panel ( 10 ) proximate to the corresponding one or more sensing electrodes ( 14, 20 ). The apparatus also includes a second circuit ( 24 ) for connection to the at least one common electrode ( 15 ). The second circuit ( 24 ) is configured to generate a second pressure signal ( 30 ) indicative of a total pressure applied to the touch panel ( 10 ). The apparatus also includes a controller ( 25 ) configured to determine an estimate of the total pressure based on a weighted difference of the second pressure signal ( 30 ) and a sum over the plurality of first pressure signals ( 29 ).

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 16/430,044, filed Jun. 3, 2019, which further claims the benefit of priority from United Kingdom Patent Application No. GB1809320.3, filed on Jun. 6, 2018, the benefit of priority of each of these applications is claimed hereby, and each is incorporated by reference herein in its entirety.

FIELD OF THE INVENTION

The present invention relates to apparatus and methods for processing signals from a pressure-sensing touch panel, and to touch panel systems using the apparatus and method.

BACKGROUND

Resistive and capacitive touch panels are used as input devices for computers and mobile devices. One type of capacitive touch panel, projected capacitance touch panels, is often used for mobile devices. An example of a projected capacitance touch panel is described in US 2010/0079384 A1.

Projected capacitance touch panels operate by detecting changes in electric fields caused by the proximity of a conductive object. The location at which a projected capacitance touch panel is touched is often determined using an array or grid of capacitive sensors. Although projected capacitance touch panels can usually differentiate between single-touch events and multi-touch events, they suffer the drawback of not being able to sense pressure. Thus, projected capacitance touch panels tend to be unable to distinguish between a relatively light tap and a relatively heavy press. A touch panel which can sense pressure can allow a user to interact with a device in new ways by providing additional information about user interaction(s) with the touch panel.

WO 2016/102975 A2 describes apparatus and methods for combined capacitance and pressure sensing in which a single signal is amplified then subsequently separated into pressure and capacitance components. WO 2017/109455 A1 describes apparatus and methods for combined capacitance and pressure sensing in which a single signal is separated into a capacitance signal, and a pressure signal which is amplified.

SUMMARY

According to a first aspect of the invention, there is provided apparatus for processing signals from a touch panel. The touch panel includes a layer of piezoelectric material disposed between a plurality of sensing electrodes and at least one common electrode. The apparatus includes a first circuit for connection to the plurality of sensing electrodes. The first circuit is configured to generate a plurality of first pressure signals. Each first pressure signal corresponds to one or more sensing electrodes and is indicative of a pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes. The apparatus also includes a second circuit for connection to the at least one common electrode. The second circuit is configured to generate a second pressure signal indicative of a total pressure applied to the touch panel. The apparatus also includes a controller configured to determine an estimate of the total pressure based on a weighted difference of the second pressure signal and a sum over the plurality of first pressure signals.

Each sensing electrode may contribute to a single first pressure signal.

The controller may be further configured to determine a location at which pressure is applied to the touch panel. A coefficient used for the weighted difference of the second pressure signal and the sum over the plurality of first pressure signals may depend upon the location.

The controller may determine the estimate of the total pressure using the equation: F _(CE)=(1−C _(CE))Q _(CE) −C _(CE) Q _(sen)

in which F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(CE) is a charge measured on the at least one common electrode, Q_(sen) is the sum of charges measured on all of the plurality of sensing electrodes, and C_(CE) is a pre-calibrated constant having a value between zero and unity. The estimate of the total pressure may be based on F_(CE).

The controller may be further configured to determine, for each of at least one first pressure signal, an estimate of the pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes, based on the first pressure signal, the second pressure signal and the total pressure.

The controller may be configured to determine a location at which pressure is applied to the touch panel. One or more coefficients used to determine the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes may depend upon the location.

The touch panel may include a number N of sensing electrodes, and the controller may determine the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes using the equation:

$F_{n} = {Q_{n} - {\frac{k_{n}}{C_{CE}}\left( {Q_{CE} - F_{CE}} \right)}}$

in which F_(n) is a piezoelectric charge induced on the n^(th) of N sensing electrodes, F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(n) is a charge measured on the n^(th) of N sensing electrodes, Q_(CE) is a charge measured on the at least one common electrode, C_(CE) is a pre-calibrated constant having a value between zero and unity, and k is a pre-calibrated constant corresponding to the n^(th) of N sensing electrodes and having a value between zero and unity. The estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes may be based on one or more corresponding values of F_(n).

The first circuit may also be configured to generate, for each first electrode, a capacitance signal indicative of a capacitance of the sensing electrode. The controller may be configured to determine a location at which pressure is applied to the touch panel based on the capacitance signals.

Generating the first pressure signals and the capacitance signals may include separating single signals received from the sensing electrodes.

Each first pressure signal may correspond to a single sensing electrode.

A touch panel system may include the apparatus, and a touch panel including a layer of piezoelectric material disposed between a plurality of sensing electrodes and at least one common electrode.

An electronic device may include the touch panel system.

According to a second aspect of the invention, there is provided a method of processing signals from a touch panel. The touch panel includes a layer of piezoelectric material disposed between a plurality of sensing electrodes and at least one common electrode. The method includes generating a plurality of first pressure signals. Each first pressure signal is based on signals received from one or more sensing electrodes. Each first pressure signal is indicative of a pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes. The method also includes generating, based on signals received from the at least one common electrode, a second pressure signal indicative of a total pressure applied to the touch panel. The method also includes determining an estimate of the total pressure based on a weighted difference of the second pressure signal and a sum over the plurality of first pressure signals.

The method may also include determining a location at which pressure is applied to the touch panel. A coefficient used for the weighted difference of the second pressure signal and the sum over the plurality of first pressure signals may depend upon the location.

Determining the estimate of the total pressure applied to the touch panel may include using the equation: F _(CE)=(1−C _(CE))Q _(CE) −C _(CE) Q _(sen)

in which F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(CE) is a charge measured on the at least one common electrode, Q_(sen) is the sum of charges measured on all of the plurality of sensing electrodes and C_(CE) is a pre-calibrated constant having a value between zero and unity. The estimate of the total pressure may be based on F_(CE).

The method may also include determining, for each of at least one first pressure signal, an estimate of the pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes, based on the first pressure signal, the second pressure signal and the total pressure.

The method may also include determining a location at which pressure is applied to the touch panel. One or more coefficients used to determine the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes may depend upon the location.

The touch panel may include a number N of sensing electrodes. Determining the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes may include using the equation:

$F_{n} = {Q_{n} - {\frac{k_{n}}{C_{CE}}\left( {Q_{CE} - F_{CE}} \right)}}$

in which F_(n) is a piezoelectric charge induced on the n^(th) of N sensing electrodes, F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(n) is a charge measured on the n^(th) of N sensing electrodes, Q_(CE) is a charge measured on the at least one common electrode, C_(CE) is a pre-calibrated constant having a value between zero and unity, and k_(n) is a pre-calibrated constant corresponding to the n^(th) of N sensing electrodes and having a value between zero and unity. The estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes may be based on one or more corresponding values of F_(n).

The method may also include generating, based on signals received from each sensing electrode, a capacitance signal indicative of a capacitance of the sensing electrode. The method may also include determining a location at which pressure is applied to the touch panel based on the capacitance signals.

Generating the first pressure signals and the capacitance signals may include separating single signals received from the sensing electrodes.

Each first pressure signal may correspond to a single sensing electrode.

BRIEF DESCRIPTION OF THE DRAWINGS

Certain embodiments of the present invention will now be described, by way of example, with reference to the accompanying drawings in which:

FIG. 1 is an equivalent circuit diagram of a piezoelectric sensor;

FIG. 2 is a circuit diagram of a first measurement circuit;

FIG. 3 is a circuit diagram of a second measurement circuit;

FIG. 4 is a circuit diagram of a third measurement circuit;

FIG. 5 is a circuit diagram of a fourth measurement circuit;

FIG. 6 is a circuit diagram of a fifth measurement circuit;

FIG. 7 is a cross-sectional view of a first touch panel for piezoelectric pressure measurements;

FIG. 8 illustrates a first apparatus for differential piezoelectric pressure measurements;

FIGS. 9 and 10 illustrate methods of obtaining differential piezoelectric pressure measurements;

FIG. 11 shows measured signals corresponding to externally induced charges on a sensing electrode and a common electrode;

FIG. 12 shows measured signals corresponding to piezoelectric induced charges on a sensing electrode and a common electrode;

FIG. 13 illustrates a second apparatus for differential piezoelectric pressure measurements;

FIGS. 14A to 14C illustrate separating superposed capacitive and piezoelectric pressure signals using an analog-to-digital convertor synchronised to a driving signal;

FIG. 15 illustrates an exemplary configuration of charge amplifiers for differential piezoelectric pressure measurements;

FIG. 16 is a plan view of a second touch panel for piezoelectric pressure measurements;

FIG. 17 is a plan view of a third touch panel for piezoelectric pressure measurements; and

FIG. 18 illustrates a third apparatus for differential piezoelectric pressure measurements.

DETAILED DESCRIPTION

In the following description, like parts are denoted by like reference numerals.

In some circumstances, a variety of unwanted signals may couple via a user's digit or conductive stylus to the sensing electrodes of a piezoelectric pressure sensing touch panel or a combined capacitance and piezoelectric pressure sensing touch panel. Such signals may be amplified along with the desired piezoelectric pressure signals, and may be of comparable or larger amplitude than piezoelectric pressure signals. For example a user's digit placed on a piezoelectric pressure sensing touch panel or a combined capacitance and piezoelectric pressure sensing touch panel sensor may couple mains interference into the sensing electrodes. Additionally or alternatively, a user may become charged with static electricity, which may couple to the sensing electrodes of a piezoelectric pressure sensing touch panel or a combined capacitance and piezoelectric pressure sensing touch panel.

Piezoelectric sensors are two electrode devices with a typically high output impedance at low frequencies, which may cause piezoelectric sensors to become vulnerable to picking up interference from external electric fields. The desired signals generated on the two electrodes of a piezoelectric sensor due to mechanical strain are of opposite polarity. By contrast, interference due to coupling to external electric fields will be of the same polarity on both electrodes. The present specification describes methods and apparatus for combining the signals from electrodes arranged on opposite sides of a layer of piezoelectric material, so that interference from coupling to external electric fields may be reduced or removed, whilst retaining or enhancing the desired piezoelectric pressure signals.

Piezoelectric Sensing:

Referring to FIG. 1, an equivalent circuit of a piezoelectric sensor 1 is shown.

A piezoelectric sensor 1 may be modelled as a voltage source, V_(piezo), in series with a capacitor, C_(piezo). The capacitance C_(piezo) represents the capacitance between first and second electrodes which are arranged with piezoelectric material between them. The voltage source V_(piezo) represents an open circuit voltage generated across the capacitance C_(piezo) when a force is applied to the piezoelectric sensor.

Referring also to FIG. 2, a first example of a measurement circuit 2 is shown.

The first measurement circuit 2 includes a single-ended amplifier A1 having inputs connected across the piezoelectric sensor 1 and a feedback network in the form of a resistor R_(fb) and capacitor C_(fb) connected in parallel across the output and the inverting input of the amplifier A1. In practice, the first measurement circuit 2 may include further passive components, switches for resetting the feedback network, and so forth. Depending upon the specific configuration used, the first measurement circuit 2 may measure a voltage, a current, a charge or a combination thereof.

Referring also to FIG. 3, a second example of a measurement circuit 3 is shown.

The second measurement circuit 3 is the same as the first measurement circuit, except that the non-inverting input of the single-ended amplifier A1 is grounded, rather than connected to an electrode of the piezoelectric sensor 1. In this way, the second measurement circuit 3 measures the current I₁ flowing into the inverting input which is at ground potential. This configuration of the second measurement circuit may reduce or eliminate the effect of parasitic capacitances. In ideal circumstances, the measured current I₁ is substantially equal to an induced piezoelectric current signal I_(piezo), i.e. I₁≈I_(piezo). Typically, the second measurement circuit 3 is configured to integrate the current signal I₁ in order to provide on the output V_(out1) a charge signal corresponding to a charge Q_(piezo) induced across the piezoelectric sensor 1. In other words, V_(out1) is functionally related to the piezoelectric charge Q_(piezo), which in turn is functionally related to a force applied to the piezoelectric sensor 1.

Referring also to FIG. 4, a third example of a measurement circuit 4 is shown.

The third measurement circuit 4 is the same as the second measurement circuit 3, except that it includes an equivalent circuit 5 representing capacitive coupling to an external source of electromagnetic interference, V_(int).

A potential issue with single-ended amplifiers A1 is that external electric fields may induce a charge on the amplifier input that may be interpreted as a piezoelectric pressure signal. This problem may occur in the piezoelectric force sensors of touch screens for piezoelectric pressure sensing or touch screens for combined capacitive touch and piezoelectric pressure sensing. A users' digit or conductive stylus applying the force to be measured is typically separated from the electrodes forming a piezoelectric force sensor by one or several thin layers of glass and/or plastic. A users' digit or conductive stylus may be at a different potential to the electrodes forming a piezoelectric force sensor. Such potential differences may arise due to, for example, electrostatic charging or coupling to other electrical sources, for example, pick-up induced by a mains power supply.

In the third measurement circuit 4, an interfering electromagnetic source V_(int) couples to both electrodes of the piezoelectric sensor 1 via a pair of capacitances C_(int1) and C_(int2). Consequently, the measured signal I₁ is a superposition of the desired piezoelectric pressure signal I_(piezo) and an unwanted interference signal I_(int1), i.e. I₁=I_(piezo)+I_(int1). The inclusion of the interference signal component I_(int1) in the measured signal I₁ may cause errors in determining an applied force, for example false detection of an applied force and/or causing the smallest reliably measurable increment of applied force to be increased.

Differential Measurements:

The current flow induced in response to polarisation P of piezoelectric material between a pair of first and second electrodes forming a piezoelectric sensor 1 has the opposite sense in each of the first and second electrodes. By contrast, interference signals induced by external sources V_(int) will have the same sign for the first and second electrodes forming a piezoelectric sensor 1.

Referring also to FIG. 5, a fourth example of a measurement circuit 6 is shown.

In the fourth measurement circuit 6, a first single-ended amplifier A1 has one input connected to a first electrode 7 of the piezoelectric sensor 1 to receive a first measurement current I₁, and the other input of the first amplifier A1 is grounded. Similarly, a second single-ended amplifier A2 has one input connected to a second electrode 8 of the piezoelectric sensor 1 to receive a second measurement current I₂, and the other input of the second amplifier A2 is grounded. A third single-ended amplifier A3 has one input connected to the output V_(out1) of the first amplifier A1 and the other input connected to the output V_(out2) of the second amplifier A2. Each of the amplifiers A1, A2, A3 has a respective resistive-capacitive feedback network R_(fb1)-C_(fb1), R_(fb2)-C_(fb2), R_(fb3)-C_(fb3).

The interfering source V_(int) is capacitively coupled to the first electrode 7 by a first capacitance C_(int1) and to the second electrode 8 by a second capacitance C_(int2). As discussed hereinbefore, the current flow I_(piezo) induced in response to polarisation P of piezoelectric material between the first and second electrode 7, 8 has the opposite sense in each of terminals 7, 8, whereas interference signals I_(int1), I_(int2) induced by the interfering source V_(int) will have the same sign. Accordingly, the first and second measurement currents may be approximated as: I ₁ =I _(int1) +I _(piezo) I ₂ =I _(int2) −I _(piezo)  (1)

The third amplifier A3 is used to obtain a difference, and when I_(int1)≈I_(int2), the output V_(out) of the third amplifier A3 will be related to: I ₁ −I ₂≈2I _(piezo)  (2)

In this way, by measuring the current flowing from both electrodes 7, 8 of the piezoelectric sensor 1 it is possible to determine a measure of the piezoelectric current I_(piezo) in which the influence of the interfering source V_(int) is reduced or removed.

In the general case, if C_(int1)≠C_(int2) and I_(int1)≠I_(int2), a weighted difference may be used. For example, if I_(int1)=α·I_(int2), in which a is a scalar constant determined from calibration experiments, then the influence of an interfering source V_(int) may be reduced or removed by obtaining: I ₁ −αI ₂=(1+α)I _(piezo)  (3)

In general, obtaining the difference of the measured signals I₁, I₂ may be performed by specifically configured circuits at the analogue signal level, or by post-processing following conversion to digital signals.

It is not necessary to know the absolute values of the interference capacitors C_(int1), C_(int2). All that is needed is the ratio α of noise introduced on the first electrode 7 to that introduced to the second electrode 8. The ratio α may be obtained from calibration experiments, for example, by deliberately introducing a test signal that mimics an interference signal V_(int) to the system and recording the response of the first and second measurement currents I₁, I₂ in the absence of applying any force to the piezoelectric sensor 1, i.e. such that I₁=I_(int1) and I₂=I_(int2). This information may be used to determine the correction ratio as α=I₁/I₂.

In practice, the correction may be performed by obtaining a difference of the first and second amplifier A1, A2 outputs V_(out1), V_(out2) in the fourth measurement circuit 6. This may be calibrated in the same way by obtaining a ratio of the outputs V_(out1), V_(out2) in response to a test signal and in the absence of any force applied to the piezoelectric sensor 1. If the ratio β=V_(out1)/V_(out2) determined from calibration is not approximately unity, then a weighted difference V_(out1)−β·V_(out2) may be obtained by inserting appropriate impedances between the outputs V_(out1), V_(out2) of the first and second amplifiers A1, A2 and the respective inputs of the third amplifier A3. Alternatively, the third amplifier A3 may be omitted and a weighted difference V_(out)−β·V_(out2) may be obtained by processing in the digital signal domain.

Referring also to FIG. 6, a fifth example of a measurement circuit 9 is shown.

In the fifth measurement circuit 9, a differential amplifier DA1 has one input connected to the first electrode 7 and the other input connected to the second electrode 8. The reduction or removal of influence of an interfering source V_(int) may be implemented in the analogue domain by setting the values of a first feedback network R_(fb1), C_(fb1) and a second feedback network R_(fb2), C_(fb2) according to the ratio between the interfering capacitances C_(int1), C_(int2). For example, by selecting C_(fb1)/C_(fb2)=C_(int1)/C_(int2). Such selection may be performed through calibration experiments similar to those described hereinbefore and by using, for example, trimmer capacitors to provide the feedback capacitances C_(fb1), C_(fb2).

Differential Measurements in Touch Panels for Piezoelectric Pressure Measurements:

In the examples described hereinbefore, differential measurements have been described in relation to piezoelectric sensors 1 in which the first and second electrodes 7, 8 may be substantially co-extensive and of simple geometry. Such a configuration permits relatively simple differential measurements. However, in a practical touch panel for piezoelectric pressure measurements or combined capacitance and piezoelectric pressure measurements, a first electrode 7 may be one of many electrodes which share a common second electrode 8. Additionally, in some example a first electrode 7 may be an electrode which additionally functions as a receiving, Rx, and/or transmitting, Tx, electrode of a capacitance measurement system. In such touch panels, the second electrode 8 may be a common counter electrode having a relatively larger, or much larger, total area than each of a number of first electrodes 7. Providing separate, matched counter electrodes for each Rx and/or Tx electrode would require an additional patterned conductive layer or layers, and the associated electrical connections. Consequently, simple differential measurements as illustrated in relation to the fourth or fifth measurement circuits 6, 9 may not be practical.

Instead, the present specification describes methods for obtaining differential measurements of piezoelectric signals from a touchscreen for piezoelectric pressure measurements or for combined capacitance and piezoelectric pressure measurements which includes at least one, unpatterned common electrode (corresponding to the second electrode 8, sometimes referred to as a counter-electrode). The methods of the present specification are also applicable (with minor modifications) to touchscreens for piezoelectric pressure measurements or for combined capacitance and piezoelectric pressure measurements in which there are two or more second electrodes 8, each being common to two or more first electrodes 7.

First Apparatus:

Referring to FIG. 7, a first example of a touch panel 10 for piezoelectric pressure measurements or combined capacitive and piezoelectric pressure measurements is shown.

The first touch panel 10 includes a first layer structure 11 having a first face 12 and a second, opposite, face 13. A number of first sensing electrodes 14 are disposed on the first face 12 of the first layer structure 11. Each of the first sensing electrodes 14 extends (or equivalently is elongated) in a first direction x, and the first sensing electrodes 14 are spaced apart in a second direction y. A common electrode 15 is disposed to substantially cover the second face 13 of the first layer structure 11.

The first layer structure 11 includes one or more layers, including at least a layer of piezoelectric material 16. Each layer included in the first layer structure 11 is generally planar and extends in first x and second y directions which are perpendicular to a thickness direction z. The one or more layers of the first layer structure 11 are arranged between the first and second faces 12, 13 such that the thickness direction z of each layer of the first layer structure 11 is substantially perpendicular to the first and second faces 12, 13.

The first touch panel 10 also includes a second layer structure 17 having a first face 18 and a second, opposite, face 19. A number of second sensing electrodes 20 are disposed on the first face 18 of the second layer structure 17. Each of the second sensing electrodes 20 extends (or equivalently is elongated) in the second direction y, and the second sensing electrodes 20 are spaced apart in a first direction x.

The second layer structure 17 includes one or more dielectric layers 21. Each dielectric layer 21 is generally planar and extends in first x and second y directions which are perpendicular to a thickness direction z. The one or more dielectric layers 21 of the second layer structure 17 are arranged between the first and second faces 18, 19 of the second layer structure 17 such that the thickness direction z of each dielectric layer 21 of the second layer structure 17 is perpendicular to the first and second faces 18, 19.

Preferably, the layer of piezoelectric material 16 includes or is formed of a piezoelectric polymer such as polyvinylidene fluoride (PVDF) or polylactic acid. However, the layer of piezoelectric material 16 may alternatively be a layer of a piezoelectric ceramic such as lead zirconate titanate (PZT). Preferably, the first and second sensing electrodes 14, 20, and the common electrode 15 are formed from silver nanowires. However, the first and second sensing electrodes 14, 20, and the common electrode 15 may alternatively be formed of transparent conductive oxides such as indium tin oxide (ITO) or indium zinc oxide (IZO). The first and second sensing electrodes 14, 20, and the common electrode 15 may be metal films such as aluminium, copper, silver or other metals suitable for deposition and patterning as a thin film. The first and second sensing electrodes 14, 20, and the common electrode 15 may be conductive polymers such as polyaniline, polythiophene, polypyrrole or poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT/PSS). The first and second sensing electrodes 14, 20, and the common electrode 15 may be formed from a metal mesh, metallic nanowires, graphene, and/or carbon nanotubes. The dielectric layer(s) 21 may include layers of a polymer dielectric material such as polyethylene terephthalate (PET) or layers of pressure sensitive adhesive (PSA) materials. However, the dielectric layer(s) 21 may include layers of a ceramic insulating material such as aluminium oxide.

The first layer structure 11 may include only the layer of piezoelectric material 16 such that the first and second opposite faces 12, 13 are faces of the piezoelectric material layer 16. Alternatively, the first layer structure 11 may include one or more dielectric layers 21 which are stacked between the layer of piezoelectric material 16 and the first face 12 of the first layer structure 11. The first layer structure 11 may include one or more dielectric layers 21 stacked between the second face 13 of the first layer structure 11 and the layer of piezoelectric material 16.

The second layer structure 17 may include only a single dielectric layer 21, such that the first and second faces 18, 19 of the second layer structure 17 are faces of a single dielectric layer 21.

Alternatively, a second layer structure 17 need not be used (see FIG. 17), and the second sensing electrodes 20 may be disposed on the first face 12 along with the first sensing electrodes (FIG. 17).

In FIG. 7, the first touch panel 10 has been shown with reference to orthogonal axes labelled x, y, and z. However, the first, second and thickness directions need not form a right handed orthogonal set.

Referring also to FIG. 8, a first apparatus 22 for differential piezoelectric pressure measurements or combined capacitance and differential piezoelectric pressure measurements is shown.

The first apparatus 22 includes the first touch panel 10, a first circuit 23, a second circuit 24 and a controller 25. Each of the first and second sensing electrodes 14, 20 is connected to the first circuit 23 by a corresponding conductive trace 26. The common electrode 15 is connected to the second circuit 24.

The first circuit 23 receives from, and may optionally transmit signals to, the first and second sensing electrodes 14, 20. The first circuit 23 measures a number of first piezoelectric pressure signals 29. The first circuit 23 is connectable to each of the first and second sensing electrodes 14, 20, in groups or individually. Each first piezoelectric pressure signal 29 corresponds to one or more of the first or second sensing electrodes 14, 20, and each first piezoelectric pressure signal 29 is indicative of a pressure acting on the touch panel 10 proximate to the respective one or more first or second sensing electrodes 14, 20. For example, the first circuit may measure or generate a first piezoelectric pressure signal 29 corresponding to each first sensing electrode 14 and a first piezoelectric pressure signal 29 corresponding to each second sensing electrode 20. Alternatively, each first piezoelectric pressure signal 29 may correspond to a pair of adjacent first or second sensing electrodes 14, 20, and so forth. Each sensing electrode 14, 20 contributes to one first piezoelectric pressure signal 29.

Optionally, the first circuit 23 may also measure mutual capacitance signals 27 corresponding to each intersection 28 of the first and second sensing electrodes 14, 20. In other examples, the first circuit 23 may instead measure self-capacitance signals corresponding to each first and second sensing electrode 14, 20. The first circuit 23 may determine the capacitance signals 27 and the first piezoelectric pressure signals 29 concurrently. Alternatively, the first circuit 23 may alternate between determining the capacitance signals 27 and the first piezoelectric pressure signals 29.

For example, the first circuit 23 may be configured for combined capacitance and piezoelectric pressure measurements as described in WO 2016/102975 A2, the entire contents of which are incorporated herein by reference. In particular, the first circuit 23 may be configured as described in relation to examples shown FIGS. 21 to 26 of WO 2016/102975 A2. Alternatively, the first circuit 23 may be configured for combined capacitance and piezoelectric pressure measurements as described in WO 2017/109455 A1, the entire contents of which are incorporated herein by reference. In particular, the first circuit 23 may be configured as described in relation to examples shown in FIGS. 4 to 21 of WO 2017/109455 A1. In other examples, the first circuit 23 may be configured as described hereinafter with reference in particular to FIGS. 13 to 17.

However, the methods of the present specification are not limited to these examples, and are applicable to any first circuit 23 which is capable of providing the hereinbefore described functions.

The second circuit 24 measures a second piezoelectric pressure signal 30 which corresponds to the common electrode 15. The second piezoelectric signal 30 should be indicative of a total pressure applied to the touch panel 10. When more than one common electrode 15 is used, a second piezoelectric signal 30 may be generated corresponding to each common electrode 15, for subsequent summation by the controller 25. Alternatively, when more than one common electrode 15 is used, the second circuit 24 may generate a single second piezoelectric signal 30 based on charges induced on all the common electrodes 15. Under ideal conditions and in the absence of external interference, a sum over the second piezoelectric pressure signals 30 and the first piezoelectric signals 29 should be approximately zero (up to a measurement error) because the sensing electrodes 14, 20 and the common electrode(s) 15 are arranged on opposite sides of any polarisation P induced in the layer of piezoelectric material 16.

The piezoelectric pressure signals 29, 30, and optionally the capacitance signals 27, are produced in response to a user interaction with the first touch panel 10, or with a layer of material overlying the first touch panel 10. In the following description, reference to a “user interaction” shall be taken to include a user touching or pressing a touch panel 10 or an overlying layer of material. The term “user interaction” shall be taken to include interactions involving a user's digit or a stylus (whether conductive or not). The term “user interaction” shall also be taken to include a user's digit or conductive stylus being proximate to a touch sensor or touch panel without direct physical contact (i.e. zero or negligible applied pressure).

The controller 25 receives the first and second piezoelectric pressure signals 29, 30, and generates corrected piezoelectric pressure values 32 which are output to a processor (not shown) which operates a device incorporating the first apparatus 22. The controller 25 generate a corrected piezoelectric pressure value 32 in the form of an estimate of the total pressure applied to the touch panel 10, based on a weighted difference of the second pressure signal 30 and a sum over the first pressure signals 29. For example, the controller 25 may generate a corrected piezoelectric pressure value 32 using Equations (13) or (21).

The controller 25 may also generate an estimate of the pressure acting on the touch panel proximate to a first sensing electrode 14, a group of first sensing electrodes 14, or each first sensing electrode 14, based on the respective first pressure signal(s) 29, the second pressure signal 30 and the total pressure. For example, the controller 25 may generate one or more corrected piezoelectric pressure values 32 Equations (24) or (26) described hereinafter. Additionally or alternatively, the controller 25 may also generate an estimate of the pressure acting on the touch panel proximate to a second sensing electrode 20, a group of second sensing electrodes 20, or each second sensing electrode 20, based on the respective first pressure signal(s) 29, the second pressure signal 30 and the total pressure. For example, the controller 25 may generate corrected one or more piezoelectric pressure values 32 using Equations (23) or (25) described hereinafter.

The controller 25 may additionally or alternatively relay the raw first and/or second piezoelectric pressure signals 29, 30 to a processor (not shown) which operates a device (not shown) incorporating the first apparatus 22. In some examples, the processor (not shown) may alternatively perform some or all of the described functions of the controller 25.

In some examples, the controller 25 may determine touch location data 31 based on the first and second pressure signals 29, 30. The touch location data 31 indicates the locations, for example x, y coordinates, of one or more user interactions. The touch location data 31 is output to the processor (not shown) which operates the device (not shown) incorporating the first apparatus 22. Coefficients used for generating corrected piezoelectric pressure values 32 in the form of an estimate of the total pressure, a pressure acting on the touch panel proximate to one or more first sensing electrodes 14, and/or a pressure acting on the touch panel proximate to one or more second sensing electrodes 20, may depend upon the location x, y.

When measured, the controller 25 receives the capacitance signals 27 and either relays them to a processor (not shown) which operates a device (not shown) incorporating the first apparatus 22, or performs further processing of the capacitance values 27. For example, the controller 25 may process the capacitance values 27 to generate the touch location data 31 for output to the processor (not shown) which operates the device (not shown) incorporating the first apparatus 22. Capacitance signals 27 may permit more accurate determination of the touch location data 31 than the first and second pressure signals 29, 30 alone.

First Method of Measurement:

Referring also to FIGS. 9 and 10, a first method of performing differential piezoelectric pressure measurements will be described.

An object 33, for example a user's digit, which is proximate to or touching the touch panel 10 may become charged to a potential V_(int) by electrostatic charging or from acting as an antenna for a source V_(int) of electromagnetic interference. There is a capacitive coupling C_(ext) between the object 33 and the overall assemblage of all of the sensing electrodes 14, 20 and the common electrode 15. A total electrostatic charge Q_(ES) is induced in the overall assemblage of all of the sensing electrodes 14, 20 and the common electrode 20 as approximately Q_(ES)=C_(ext)·V_(int). It should be noted that it may not be possible to calibrate C_(ext) in practice, because the precise geometry will be continually changing as a user moves their digit and/or stylus in relation to the touch panel 10, and also will vary between different users and different digits of the same user. Additionally, V_(int) may not be measurable in general.

The first method of the specification is based on the premise that an unknown, total electrostatic charge Q induced on the electrodes 14, 15, 20 will be made up of a sum of individual electrostatic charges induced on each of the electrodes 14, 15, 20.

Hereinafter, the m^(th) of M first sensing electrodes 14 may alternatively be denoted as y_(m) and the n^(th) of N second sensing electrodes 20 may alternatively be denoted as x_(n). If the electrostatic charge induced on the n^(th) of N second sensing electrodes 20, x_(n) by the object 33 is denoted Sx_(n) and so forth, the electrostatic charge induced on the m^(th) of M first sensing electrodes 14, y_(m) by the object 33 is denoted Sy_(m) and so forth, and the electrostatic charge induced on the counter electrode 15 by the object 33 is denoted S_(CE), then the total electrostatic charge Q_(ES) may be approximated as:

$\begin{matrix} {Q_{ES} = {{\sum\limits_{n = 1}^{N}{Sx}_{n}} + {\sum\limits_{m = 1}^{M}{Sy}_{m}} + S_{CE}}} & (4) \end{matrix}$

The electrostatic charges Sx_(n), Sy_(m), S_(CE) induced on individual electrodes x_(n), y_(m), 15 may alternately be expressed as fractions of the total electrostatic charge induced Q_(ES). For example, the electrostatic charge Sx_(n) may be written as Sx_(n)=k_(n)·Q_(ES), in which k_(n) is the fraction of the total electrostatic charge Q_(ES) induced on the n^(th) of N second sensing electrodes x_(n). Similarly, the electrostatic charge Sy_(m) may be written as Sy_(m)=h_(m)·Q_(ES), in which h_(M) is the fraction of the total electrostatic charge Q_(ES) induced on the m^(th) of M first sensing electrodes y_(m). Further, the electrostatic charge S_(CE), may be written as

S_(CE)=C_(CE)·Q_(ES), in which C_(CE) is the fraction of the total electrostatic charge Q_(ES) induced on the counter electrode 15. Substituting these expressions Equation (4):

$\begin{matrix} {{Q_{ES} = {{\sum\limits_{n = 1}^{N}{k_{n}Q_{ES}}} + {\sum\limits_{m = 1}^{M}{h_{m}Q_{ES}}} + {C_{CE}Q_{ES}}}}{1 = {{\sum\limits_{n = 1}^{N}k_{n}} + {\sum\limits_{m = 1}^{M}h_{m}} + C_{CE}}}{1 = {C_{x} + C_{y} + C_{CE}}}} & (5) \\ {{in}\mspace{14mu}{which}\text{:}} & \; \\ {{C_{x} = {\sum\limits_{n = 1}^{N}k_{n}}},{C_{y} = {\sum\limits_{m = 1}^{M}h_{m}}}} & (6) \end{matrix}$

In general, the fractions k_(n), h_(m), C_(x), C_(y) and C_(CE) will all be a function of the touch coordinates, denoted x, y, at which the object 33 contacts the touch panel 10. In other words, the fraction k_(n) is typically not a constant, and may be a function k_(n)(x,y) of the touch coordinates x, y. Similarly, the other fractions may also functions of touch position, namely h_(m)(x,y), C_(x)(x,y), C_(y)(x,y) and C_(CE)(x,y). The fractions k_(n), h_(m), C_(x), C_(y) and C_(CE) may be calibrated by performing appropriate calibration experiments with known V_(int) and known touch positions x, y. However, because of the position dependent nature of the fractions k_(n), h_(m), C_(x), C_(y) and C_(CE), full calibration may require a large number of calibration experiments to be performed for a given touch panel 10.

When polarisation P of the piezoelectric material layer 16 is induced between the common electrode 15 and the sensing electrodes x_(n), y_(m), the charges induced on the sensing electrodes x_(n), y_(m) have opposite polarity to the charges induced on the common electrode 15. In other words, external coupling to the object 33 induces charge flow between system ground or common mode voltage and the overall assemblage of all of the electrodes x_(n), y_(m), 15, whereas by contrast a polarisation P of the piezoelectric material layer 16 induces charge to flow between the counter electrode 15 and the sensing electrodes x_(n), y_(m). One consequence, as explained hereinbefore, is that charges induced by the polarisation P of the piezoelectric material layer 16 are expected to sum to zero, at least to within a measurement error.

If the piezoelectric charge induced on the n^(th) of N second sensing electrodes x_(n) by a polarisation P of the piezoelectric material layer 16 is denoted Fx_(n) and so forth, the piezoelectric charge induced on the m^(th) of M first sensing electrodes y_(n) by a polarisation P of the piezoelectric material layer 16 is denoted Fy_(m) and so forth, and the piezoelectric charge induced on the counter electrode 15 by a polarisation P of the piezoelectric material layer 16 is denoted F_(CE), then a total induced piezoelectric charge Q_(PT) may be approximated as:

$\begin{matrix} {Q_{PT} = {0 = {{\sum\limits_{n = 1}^{N}{Fx}_{n}} + {\sum\limits_{m = 1}^{M}{Fy}_{m}} + F_{CE}}}} & (7) \end{matrix}$

It may be noted that the piezoelectric charge F_(CE) induced on the counter electrode 15 may provide a good measure of the total force applied to the touch panel 10.

Referring in particular to FIG. 10, the charge induced on the n^(th) of N second sensing electrodes x_(n), 20 may be written as: Qx _(n) =Sx _(n) +Fx _(n) Qx _(n) =k _(n) Q _(ES) +Fx _(n)  (8)

Similarly, the charge induced on the m^(th) of M first sensing electrodes y_(m), 14 may be written as: Qy _(m) =h _(m) Q _(ES) +Fy _(m)  (9)

and the charge induced on the counter electrode 15 may be written as: Q _(CE) =C _(CE) Q _(ES) +F _(CE)  (10)

In the first method of measurement, the charges Qx_(n), Qy_(m) measured by all of the sensing electrodes x_(n), y_(m) are summed to yield:

$\begin{matrix} {{Q_{sen} = {{\sum\limits_{n = 1}^{N}{Qx}_{n}} + {\sum\limits_{m = 1}^{M}{Qy}_{m}}}}{Q_{sen} = {{\sum\limits_{n = 1}^{N}\left( {{k_{n}Q_{ES}} + {Fx}_{n}} \right)} + {\sum\limits_{m = 1}^{M}\left( {{h_{m}Q_{ES}} + {Fy}_{m}} \right)}}}{Q_{sen} = {{Q_{ES}\left( {{\sum\limits_{n = 1}^{N}k_{n}} + {\sum\limits_{m = 1}^{M}h_{m}}} \right)} + {\sum\limits_{n = 1}^{N}{Fx}_{n}} + {\sum\limits_{m = 1}^{M}{Fy}_{m}}}}{Q_{sen} = {{Q_{ES}\left( {1 - C_{CE}} \right)} - F_{CE}}}} & (11) \end{matrix}$

In which Q_(sen) is the sum of all the charges measured by all of the sensing electrodes x_(n), y_(m), and in which Equations (5) and (7) have been employed to obtain the final expression for the Q_(sen). The total induced electrostatic charge Q_(ES) may be eliminated between Equations (10) and (11) to yield:

$\begin{matrix} {\frac{Q_{CE} - F_{CE}}{C_{CE}} = {Q_{ES} = \frac{Q_{sen} + F_{CE}}{\left( {1 - C_{CE}} \right)}}} & (12) \end{matrix}$

Which may re-arranged for the piezoelectric charge F_(CE) induced on the counter electrode 15 as: F _(CE)=(1−C _(CE))Q _(CE) −C _(CE) Q _(sen)  (13)

In which the charge Q_(CE) induced on the counter electrode 15 may be measured, the summed charge Q_(sen) on the sensing electrodes x_(n), y_(n) may be obtained by summing all of the measured charges Qx₁, Qx₂, . . . , Qx_(N) and Qy₁, Qy₂, . . . , Qy_(M). The fraction C_(CE) may be determined in advance through calibration experiments using an object 33 charged, connected or coupled to a known interfering potential V_(int) and at a known location x, y with respect to the touch panel 10. As mentioned hereinbefore, the fraction C_(CE) is in general a function of touch location x, y, i.e. C_(CE)=C_(CE)(x,y). The appropriate value of C_(CE)(x,y) may be obtained, for example, by using capacitance signals 27 or touch location data 31 to provide the touch location x, y. Alternatively, in a piezoelectric only touch panel system, the touch location x, y may be inferred from the raw first piezoelectric signals 29.

In this way, using the first method and Equation (13), a total piezoelectric charge F_(CE) may be determined in which the effects of external electrical interference from an object 33 may be reduced or eliminated. The total piezoelectric charge F_(CE) depends on the straining of the piezoelectric material layer 16, and hence depends on the force applied to the touch panel 10 by a user input.

In practice, the charges Qx_(n), Qy_(n), Q_(CE) may be detected using charge amplifiers 34, such that a voltage output corresponding to the n^(th) of N second sensing electrodes x_(n), 20 is Vx_(n), and is related to Qx_(n) and so forth. Commonly, a charge amplifier 34 will integrate the input current. For example, if the current on the n^(th) of N second sensing electrodes x_(n) is Ix_(n), then the voltage Vx_(n) on the n^(th) of N second sensing electrodes x_(n) at a time t may, under ideal conditions, be expressed as:

$\begin{matrix} {{Vx}_{n} = {{{Gx}_{n}{Qx}_{n}} = {{Gx}_{n}{\overset{t}{\int\limits_{0}}{{{Ix}_{n}(\tau)}d\;\tau}}}}} & (14) \end{matrix}$

In which Gx_(n) is the gain of the n^(th) of N charge amplifiers 34 connected to the N second sensing electrodes x_(n) and τ is an integration variable. Similarly, the voltage on the m^(th) of M first sensing electrodes y_(m) may be expressed as: Vy _(m) =Gy _(m) Qy _(m) =Gy _(m)∫₀ ^(t) Iy _(m)(τ)dτ  (15)

In which Gy_(m) is the gain of the m^(th) of M charge amplifiers 34 connected to the M first sensing electrodes y_(n), Iy_(m) is the current on the m^(th) of M first sensing electrodes y_(m) and τ is an integration variable. Similarly, the voltage on the common electrode may be expressed as: V _(CE) =G _(CE) Q _(CE) =G _(CE)∫₀ ^(t) I _(CE)(τ)dτ  (16)

In which G_(CE) is the gain of the charge amplifier 34 connected to the common electrode 15, I_(CE) is the current on the common electrode 15 and τ is an integration variable. The charge amplifier signals 34 corresponding to all of the sensing electrodes x_(n), y_(m) may then be summed to yield a summed voltage signal, V_(sen):

$\begin{matrix} {{V_{sen} = {{\sum\limits_{n = 1}^{N}{Vx}_{n}} + {\sum\limits_{m = 1}^{M}{Vy}_{m}}}}{V_{sen} = {{\sum\limits_{n = 1}^{N}{{Gx}_{n}{Qx}_{n}}} + {\sum\limits_{m = 1}^{M}{{Gy}_{m}{Qy}_{m}}}}}} & (17) \end{matrix}$

If the gains are all substantially equal such that Gx_(n)≈Gy_(m)≈G, with G denoting a common gain value, then Equation (17) may be simplified to:

$\begin{matrix} {{V_{sen} = {G\left( {{\sum\limits_{n = 1}^{N}{Qx}_{n}} + {\sum\limits_{m = 1}^{M}{Qy}_{m}}} \right)}}{V_{sen} = {GQ}_{sen}}{V_{sen} = {G\left( {{Q_{ES}\left( {1 - C_{CE}} \right)} - F_{CE}} \right)}}} & (18) \end{matrix}$

Similarly, if G_(CE)≈G, then Equation (10) may be re-written in terms of the corresponding charge amplifier 34 output as: V _(CE) =GQ _(CE) V _(CE) =G(C _(CE) Q _(ES) +F _(CE))  (19)

Eliminating Q_(ES) between Equations (18) and (19) the voltage analogue of Equation (12) may be obtained as:

$\begin{matrix} {\frac{\frac{V_{CE}}{G} - F_{CE}}{C_{CE}} = {Q_{ES} = \frac{\frac{V_{sen}}{G} + F_{CE}}{\left( {1 - C_{CE}} \right)}}} & (20) \end{matrix}$

Equation (20) may equally be obtained by simply substituting Q_(CE)=V_(CE)/G and Q_(sen)=V_(sen)/G into Equation (12). Re-arranging Equation (20) for F_(CE), or equivalently substituting Q_(CE)=V_(CE)/G and Q_(sen)=V_(sen)/G into Equation (13) yields an expression for the piezoelectric charge F_(CE) induced on the counter electrode 15 in terms of charge amplifier 34 voltage outputs as:

$\begin{matrix} {F_{CE} = {{\left( {1 - C_{CE}} \right)\frac{V_{CE}}{G}} - {C_{CE}\frac{V_{sen}}{G}}}} & (21) \end{matrix}$

Thus, it is apparent that provided the charge amplifier 34 gains are approximately equal to a common gain, G, i.e. Gx_(n)≈Gy_(m)≈G_(CE)≈G, then the relationships derived in terms of induced charges may be equally applicable to the corresponding outputs of charge amplifiers 34. Of course, perfect identity would not be expected in practical circumstances because the charge amplifier 34 gains Gx_(n), Gy_(m), G_(CE) will not be perfectly identical to a common gain value G. Furthermore, each charge amplifier 34 will in practice experience DC offsets and drift, in addition to time-dependent decay of low frequency and DC components in the voltage output (sometimes referred to as “roll-off”). Nonetheless, provided that the charge amplifier 34 gains are approximately equal to a common gain value G, i.e. Gx_(n)≈Gy_(m)≈G_(CE)≈G, Equation (21) may be used to generate a corrected signal 32 in which the influence of coupling to external electrical fields may be at least partially cancelled.

Second Method of Measurement:

The second method of measurement is an extension of the first method of measurement, and may be used to estimate values of piezoelectric charge Fx_(n), Fy_(m) for individual sensing electrodes x_(n), y_(m), based on a weighted correction using the charge Q_(CE) measured on the counter electrode 15 and the estimated piezoelectric charge F_(CE) on the counter electrode 15.

Referring again to Equation (8) for the n^(th) of N second sensing electrodes x_(n), 20: Qx _(n) =k _(n) Q _(ES) +Fx _(n)  (8)

Referring again to Equation (10), for the counter electrode 15: Q _(CE) =C _(CE) Q _(ES) +F _(CE)  (10)

Eliminating the total electrostatic charge Q_(CE) between Equations (8) and (10):

$\begin{matrix} {\frac{{Qx}_{n} - {Fx}_{n}}{k_{n}} = {Q_{ES} = \frac{Q_{CE} - F_{CE}}{C_{CE}}}} & (22) \end{matrix}$

Which may be re-arranged for the piezoelectric charge Fx_(n) of the n^(th) of N second sensing electrodes x_(n), 20 as:

$\begin{matrix} {{Fx}_{n} = {{Qx}_{n} - {\frac{k_{n}}{C_{CE}}\left( {Q_{CE} - F_{CE}} \right)}}} & (23) \end{matrix}$

In which the charge Q_(CE) induced on the counter electrode 15 may be measured and the charge Qx_(n) induced on the n^(th) of N second sensing electrodes x_(n), 20 may be measured. The total piezoelectric charge F_(CE) may be determined from the first method using the Equation (13). The fractions k_(n) and C_(CE) may be determined in advance through calibration experiments performed using an object 33 charged, connected or coupled to a known interfering potential V_(int), whilst the object 33 is arranged at a known location x, y with respect to the touch panel 10. As mentioned hereinbefore, the fractions k_(n) and C_(CE) are in general functions of touch location x, y, i.e. k_(n)=k_(n) (x,y) and C_(CE)=C_(CE)(x,y). The appropriate values of k_(n) (x,y) and C_(CE)(x,y) may be obtained by using the capacitance signals 27 or touch location data 31 to provide the touch location x, y.

In this way, a piezoelectric charge Fx_(n) for the n^(th) of N second sensing electrodes x_(n), 20 may be estimated for which the effects of external interference from a non-ground potential of the object 33 are reduced or eliminated.

Similarly, for the m^(th) of M first sensing electrodes y_(m), 14, a piezoelectric charge Fy_(m) for which the effects of external interference from a non-ground potential of the object 33 are reduced or eliminated may be obtained using:

$\begin{matrix} {{Fy}_{m} = {{Qy}_{m} - {\frac{h_{m}}{C_{CE}}\left( {Q_{CE} - F_{CE}} \right)}}} & (24) \end{matrix}$

In practice, the charges Qx_(n), Qy_(m), Q_(CE) may be detected using charge amplifiers 34, such that a voltage output corresponding to the n^(th) of N second sensing electrodes x_(n), 20 is Vx_(n), and so forth. Similar to the first method, if the charge amplifier 34 gains are approximately equal to a common gain value G, i.e. Gx_(n)≈Gy_(m)≈G_(CE)≈G, then Equation (23) may be re-expressed in terms of charge amplifier 34 voltage outputs as:

$\begin{matrix} {{Fx}_{n} = {\frac{{Vx}_{n}}{G} - {\frac{k_{n}}{C_{CE}}\left( {\frac{V_{ce}}{G} - F_{CE}} \right)}}} & (25) \end{matrix}$

Similarly, Equation (24) may be re-expressed in terms of charge amplifier 34 voltage outputs as:

$\begin{matrix} {{Fy}_{m} = {\frac{{Vy}_{m}}{G} - {\frac{h_{m}}{C_{CE}}\left( {\frac{V_{CE}}{G} - F_{CE}} \right)}}} & (26) \end{matrix}$

Experimental Data:

Referring also to FIG. 11, experimental data illustrating externally induced charges on a sensing electrode x_(n), y_(m) and the common electrode 15 are shown.

A first voltage signal 35 (solid line) corresponds to a charge amplifier 34 output measured for the common electrode 15. A second voltage signal 36 (dashed line) corresponds to a charge amplifier output measured for a sensing electrode x_(n), y_(m). The signals 35, 36 shown in FIG. 1 were obtained using an object 33 in the form of a digit charged to an electrostatic potential and held nearly touching a touch panel 10. No pressure was applied to the touch panel 10.

It may be observed that in FIG. 11, the first and second voltage signals 35, 36 have corresponding signs (in other words the signals have substantially the same polarities at a given time).

Referring also to FIG. 12, experimental data illustrating piezoelectric induced charges on a sensing electrode x_(n), y_(m) and the common electrode are shown.

The first and second voltage signals 35, 36 correspond respectively to the common electrode 15 and a sensing electrode x_(n), y_(m) in the same way as FIG. 11. However, the data shown in FIG. 12 was captured in response to tapping the touch panel 10 using a non-conductive object, in order to generate piezoelectric pressure signals which are substantially free of noise from external electric fields.

It may be observed that in FIG. 12, the first and second voltage signals 35, 36 have opposite signs (in other words the signals have substantially opposite polarities at a given time).

The observed polarities do not precisely correspond to the ideal case in either of FIG. 11 or 12, which is thought to be as a result of small variations in DC offsets and other sources of measurement error.

Second Apparatus:

Apparatuses for combined capacitance and pressure sensing have been described in WO 2016/102975 A2, in particular with reference to FIGS. 22 to 26 of this document.

In order to aid understanding of the second apparatus 37 (FIG. 13) of the present specification, it may be helpful to briefly discuss the operation of apparatuses for combined capacitance and pressure sensing as described in WO 2016/102975 A2. The discussion hereinafter is made with reference to the structure of the first touch panel 10 of the present specification.

The layer of piezoelectric material 16 is poled. Consequently, the pressure applied by a user interaction will cause a strain which induces a polarisation P of the layer of piezoelectric material 16. The polarisation P of the layer of piezoelectric material 16 results in an induced electric field E_(p), which has a component E_(z) in the thickness direction. The deformation which produces the polarisation P may result from a compression or a tension. The deformation which produces the polarisation P may be primarily an in-plane stretching of the piezoelectric material layer 16 in response to the applied pressure of a user interaction.

The induced electric field E_(p) produces a potential difference between the common electrode 15 and any one of the sensing electrodes 14, 20. Electrons flow on or off the electrodes 14, 15, 20 until the induced electric field E_(p) is cancelled by an electric field E_(q) produced by the charging of the electrodes 14, 15, 20. In other words, the electric field E_(q) results from the charges Fx_(n), Fy_(m), F_(CE).

When the touch panel 10 is used for combined capacitance and pressure sensing, signals received from the sensing electrodes 14, 20 generally take the form of a superposition of a piezoelectric signal pressure signal and an applied or sensed capacitance measurement signal. Apparatuses for combined capacitance and pressure sensing as described in WO 2016/102975 A2, in particular with reference to FIGS. 22 to 26, operate by using first and second frequency dependent filters (not shown) to separate signals received from the sensing electrodes 14, 20 into a first component including capacitance information and a second component including piezoelectric pressure information. The first and second frequency dependent filters (not shown) may be physical filters, or may be applied during digital signal processing. This is possible because piezoelectric pressure signals and capacitance measurement signals generally have different, separable frequency contents.

For example, mutual capacitances between a pair of sensing electrodes 14, 20 may typically fall within the range of 0.1 to 3000 pF or more, and preferably 100 to 2500 pF. In order to effectively couple to capacitances in this range, a capacitance measurement signal may typically have a base frequency of greater than or equal to 10 kHz, greater than or equal to 20 kHz, greater than or equal to 50 kHz or greater than or equal to 100 kHz. By contrast, piezoelectric pressure signals typically include a broadband frequency content spanning a range from several Hz to several hundreds or thousands of Hz. This is at least in part because piezoelectric pressure signals arise from user interactions by a human user.

Referring also to FIG. 13, a second apparatus 37, for combined capacitance and differential piezoelectric pressure measurements, is shown.

In the apparatuses described in WO 2016/102975 A2, the first and second frequency dependent filters (not shown) are implemented in hardware as a part of front end modules, or in the digital domain, for example by a controller.

By contrast, the second apparatus 37 of the present specification implements first frequency dependent filters to select the first piezoelectric pressure signals 29 using analog-to-digital converters (ADC) 38 a, 38 b which are synchronised with a capacitance measurement signal 39 at a first sampling frequency f_(piezo). The second apparatus 37 implements a second frequency dependent filter in the digital domain to obtain capacitance signals 27. For example, by application of a digital high-pass filter, or by using the more recently sample value, or values, of the first piezoelectric pressure signals 29 to provide a baseline.

The second apparatus 37 includes a first touch panel 10 and a touch controller 40 for combined capacitance and differential pressure sensing. The second apparatus 37 may be incorporated into an electronic device (not shown) such as, for example, a mobile telephone, a tablet computer, a laptop computer and so forth. The first touch panel 10 may be bonded overlying the display (not shown) of an electronic device (not shown). In this case, the materials of the first touch panel 10 should be substantially transparent. A cover lens (not shown) may be bonded overlying the first touch panel 10. The cover lens (not shown) is preferably glass but may be any transparent material.

The touch controller 40 includes a controller 25. The touch controller 40 also includes a first circuit 23 including a pair of amplifier modules 41 a, 41 b a pair of multiplexers 42 a, 42 b, a pair of primary ADCs 38 a, 38 b and a pair of secondary ADCs 43 a, 43 b. The touch controller also includes a second circuit 24 including a common electrode charge amplifier 44 and a common electrode ADC 45. The controller 25 may communicate with one or more processors (not shown) of an electronic device (not shown) using a link 46. The controller 25 includes a signal source (not shown) for providing a driving capacitance measurement signal 39, V_(sig)(t)(FIG. 14, also referred to as “driving signal” for brevity hereinafter) to one or both of the amplifier modules 41 a, 41 b).

The second apparatus 37 will be described with reference to an example in which the driving signal 39, V_(sig)(t) is supplied to the first amplifier module 41 a, such that the first sensing electrodes 14 are transmitting, Tx electrodes, and the second sensing electrodes 20 are receiving, Rx electrodes.

Each amplifier module 41 a, 41 b includes a number of separate charge amplifiers 34. Each charge amplifier 34 of the first amplifier module 41 a is connected to a corresponding first sensing electrode 14 via a conductive trace 26. The output of each charge amplifier 34 of the first amplifier module 41 a is connected to a corresponding input of the first multiplexer 42 a. In this way, the first multiplexer 42 a may output an amplified signal 47 a corresponding to an addressed first sensing electrode 14.

The first primary ADC 38 a receives the amplified signal 47 a corresponding to a presently addressed first sensing electrode 14 from the first multiplexer 42 a output. The amplified signal 47 a corresponding to a presently addressed first sensing electrode 14 includes a superposition of the driving signal 39, V_(sig)(t) and a piezoelectric pressure signal 29, V_(piezo)(t). The first primary ADC 38 a also receives a first synchronisation signal 48 a from the controller 25 (also referred to as a “clock signal”). The first synchronisation signal 48 a triggers the first primary ADC 38 a to obtain samples at a first sampling frequency f_(piezo) and at times corresponding to the amplitude of the driving signal 39, V_(sig)(t) being substantially equal to a ground, common mode or minimum value. In this way, the first primary ADC 38 a may obtain a first filtered signal 49 a in the form of a sampled signal which corresponds approximately to a piezoelectric pressure signal 29, V_(piezo)(t) generated by the first sensing electrode 14 connected with the first multiplexer 42 a. The first synchronisation signal 48 a need not trigger the first primary ADC 385 to obtain samples during every single period of the driving signal 39, V_(sig)(t), and instead may trigger the first primary ADC 38 a to obtain samples during, for example, every other period, every tenth period, every hundredth period and so forth.

For example, referring also to FIGS. 14A to 14C, an example of obtaining a piezoelectric pressure signal 29 in the form of the first filtered signal 49 a is illustrated.

For visual purposes, in FIGS. 14A to 14C, the driving signal 39, V_(sig)(t) and a superposed piezoelectric pressure signal 29, V_(piezo)(t) have been illustrated with much smaller disparities in frequency and amplitude than would be expected in practice. In practice, the driving signal 39, V_(sig)(t) would be expected to have a significantly larger amplitude and to vary at a frequency several orders of magnitude larger than the piezoelectric pressure signal 29, V_(piezo)(t).

Referring in particular to FIG. 14A, an example of a driving signal 39, V_(sig)(t) of base frequency f_(d) may take the form a pulsed wave with a 50:50 duty ratio and a period of 1/f_(d). In this example, the first synchronisation signal 48 a triggers the first primary ADC 38 a at approximately the midpoint of the driving signal 39, V_(sig)(t) minimum, or zero, period. For example, the first primary ADC 38 a may obtain a sample at times t₁, t₂=t₁+1/f_(d), t₃=t₁+2/f_(d) and so forth.

Referring in particular to FIG. 14B, with the first sensing electrodes 14 acting as transmitter electrodes, Tx, and the second sensing electrodes 20 acting as receiving electrodes, Rx, the amplified signal 47 a may be approximated as a superposition of a piezoelectric pressure signal 29, V_(piezo)(t) and the driving signal 39 V_(sig)(t). The first synchronisation signal 48 a triggers sampling of the amplified signal 47 a at times when the contribution of the driving signal 39, V_(sig)(t) to the amplified signal 47 a is substantially equal to a ground, common mode or minimum value. In this way, a sampling of substantially only the piezoelectric pressure signal 29, V_(piezo)(t) may be obtained.

Referring in particular to FIG. 14C, the first filtered signal 49 a then takes the form of a sequence of samplings of the piezoelectric pressure signal 29, V_(piezo)(t) at times t₁, t₂, t₃ and so forth.

The first secondary ADC 43 a receives the amplified signal 47 a corresponding to a presently addressed first sensing electrode 14 from the first multiplexer 42 a output. The first secondary ADC 43 a samples the amplified signal 47 a at a sampling frequency f_(cap), which is at least several times the base frequency f_(d) of the driving signal 39, V_(sig)(t). The first secondary ADC 43 a outputs a digitised amplified signal 50 a to the controller 25. The controller 25 receives the digitised amplified signal 50 a and applies a digital high pass filter to obtain a second filtered signal in the digital domain. The second filtered signal corresponds to capacitance signals 27.

Alternatively, since the piezoelectric pressure signal 29, V_(piezo)(t) typically varies at frequencies several orders of magnitude lower than the base frequency f_(d) of the driving signal 39, V_(sig)(t), the controller 25 may treat the most recently sampled value of the first filtered signal 49 a, for example V_(piezo) (t₃), as an additional offset and subtract this value from the digitised amplified signal 50 a. More accurate baseline corrections may be employed, for example, linear interpolation based on the two most recent sampled values of the first filtered signal 49 a, or quadratic interpolation based on the three most recently sampled values of the first filtered signal 49 a.

The primary and secondary ADCs 38 a, 43 a may be the same. However, it may be advantageous for the primary and secondary ADCs 38 a, 43 a to be different. In particular, the primary ADC 38 a may be optimised for the dynamic range of the piezoelectric pressure signals 29, V_(piezo)(t), without the need to measure the larger amplitudes corresponding to the driving signal V_(sig)(t). Furthermore, because the first sampling frequency f_(piezo) should beat most equal to the base frequency f_(d) of the capacitance measurement signal 39, V_(sig)(t), a lower bandwidth is required for the primary ADC 38 a compared to the secondary ADC 43 a. For cost sensitive applications, this enables use of cheaper, ADCs for the primary ADC 38 a. By contrast, for performance applications, this enables the use of more precise ADCs capable of differentiating a larger number of signal levels within the same dynamic range (a 16-bit ADC is typically slower than an 8-bit ADC all else being equal).

The processing of signals from the second sensing electrodes 20 is similar to that of signals from the first sensing electrodes 14, except that because the second sensing electrodes 20 are the receiving, Rx electrodes, a second synchronisation signal 48 b for the second primary ADC 38 b may be offset with respect to the first synchronisation signal 48 a.

Each charge amplifier 34 of the second amplifier module 41 b is connected to a corresponding second sensing electrode 20 via a conductive trace 26, and the output of each charge amplifier 34 of the second amplifier module 41 b is connected to a corresponding input of the second multiplexer 42 b. In this way, the second multiplexer 42 b may output an amplified signal 47 b corresponding to an addressed second sensing electrode 20.

The amplified signal 47 b corresponding to a presently addressed second sensing electrode 20 includes a superposition of a received capacitance measurement signal (not shown) V_(meas)(t) and a piezoelectric pressure signal 29, V_(piezo)(t). The received capacitance measurement signal V_(meas)(t) (referred to as a “received signal” for brevity hereinafter) is the driving signal 39, V_(sig)(t) as coupled to the addressed second sensing electrode 20 by a mutual capacitance between the addressed second sensing electrode 20 and a first sensing electrode 14. The received signal V_(meas)(t) is related to and has a similar form to the driving signal 39, V_(sig)(t), and in particular has substantially the same frequency contents. However, the received signal V_(meas)(t) may include a change in amplitude and/or a change in phase compared to the driving signal V_(sig) (t). The second primary ADC 38 b receives a second synchronisation signal 48 b from the controller 25 (also referred to as a “clock signal”). The second synchronisation signal 48 b triggers the second primary ADC 38 b to obtain samples at the sampling frequency f_(piezo) and at times corresponding to the amplitude of the received signal V_(meas)(t) being substantially equal to a ground, common mode or minimum value. Depending on the form of the driving signal 39, V_(sig)(t) and the typical phase shifts between driving signals 39, V_(sig)(t) and the received signals V_(meas)(t), there are several possible relationships between the first and second synchronisation signals 48 a, 48 b.

When the received signal V_(meas)(t) is approximately in phase with the driving signal 39, V_(sig)(t), the second synchronisation signal 48 b may be the same as the first synchronisation signal 48 a. The second synchronisation signal 48 b will trigger sampling of the amplified signal 47 b at times when the contribution of the received signal V_(meas)(t) to the amplified signal 47 b is substantially equal to a ground, common mode or minimum value. In this way, a sampling of substantially only the piezoelectric pressure signal 29, V_(piezo)(t) may be obtained.

Similarly, for a driving signal 39, V_(sig)(t) in the form of a pulsed wave as shown in FIG. 14A, small phase shifts φ of up to about φ±π/2 between the received signal V_(meas)(t) and the driving signal 39, V_(sig)(t) may be accommodated without requiring any offset between the first and second synchronisation signals 48 a, 48 b. For a pulsed wave, such phase shifts can be tolerated because the driving signal 39, V_(sig)(t) and received signal V_(meas)(t) are each substantially equal to zero for half of each period.

For larger phase shifts φ or different, non-square, waveforms of the driving signal 39, V_(sig)(t), the second synchronisation signal 48 b may be offset with respect to the first synchronisation signal 48 a such that, within the range of capacitances expected/measured for the corresponding touch panel 10, the second synchronisation signal 48 b triggers the second primary ADC 38 b during a period of low or zero signal level of the received signal V_(meas)(t). In other words, the second synchronisation signal 48 b may synchronise the sampling of the second primary ADC 38 b to the received signal V_(meas)(t), instead of the driving signal 39, V_(sig)(t).

Alternatively, the second synchronisation signal 48 b could be generated in response to a condition on the received signal V_(meas)(t). For example, a simple comparator circuit could be used to generated the second synchronisation signal 48 b in response to the received signal V_(meas)(t) dropping to within a pre-calibrated range of ground, common mode or a minimum value. A circuit triggering the second synchronisation signal 48 b may include a delay timer.

In this way, the second primary ADC 38 b may obtain a second filtered signal 49 b in the form of a sampled signal which corresponds approximately to a piezoelectric pressure signal 29, V_(piezo)(t) generated by the second sensing electrode 20 connected via the second multiplexer 42 b. The second synchronisation signal 48 b need not trigger the second primary ADC 38 b to obtain samples during every single period of the driving signal 39, V_(sig)(t) or measured signal V_(meas)(t), and instead may trigger the second primary ADC 38 b to obtain samples during, for example, every other period, every tenth period, every hundredth period and so forth.

The controller 25 may also provide a second synchronisation signal 51 to the multiplexers 42 a, 42 b and/or amplifiers 34. The second synchronisation signal 51 may cause the multiplexers 42 a, 42 b to address each combination of first and second sensing electrodes 14, 20 according to a sequence determined by the controller 25. In this way, the touch controller 25 may receive amplified signals 47 a, 47 b from each pairing of first and second sensing electrodes 14, 20 according to a sequence determined by the controller 25. The sequence may be pre-defined, for example, the sequence may select each pair of a first sensing electrode 14 and a second sensing electrode 20 once before repeating. The sequence may be dynamically determined, for example, when one or more user interactions are detected, the controller 25 may scan the subset of first and second sensing electrodes 14, 20 adjacent to each detected user interaction in order to provide faster and/or more accurate tracking of user touches.

The common electrode charge amplifier 44 receives signals from the common electrode 15 and generates a common electrode amplified signal 52. The common electrode ADC 45 receives the common electrode amplified signal 52 and samples it at the piezoelectric sampling frequency f_(piezo) to generate the second piezoelectric signal 30. Optionally, the common electrode ADC 45 is also synchronised by a third synchronisation signal 48 c, which may be identical to or offset from the first synchronisation signal, so as to sample the second piezoelectric signal 30 at times corresponding to ground, common mode or a minimum value of the driving signal 39, V_(sig)(t) and/or ground, common mode or a minimum value the received signal V_(meas)(t). Synchronisation of the common electrode ADC 45 may help to reduce or avoid cross-talk from the capacitance measurements.

Based on the obtained filtered signals 49 a, 49 b the controller 25 may calculate pressure values 32 a, 32 b corresponding to the addressed first and second sensing electrodes 14, 20. The pressure values 32 a, 32 b are determined based on the first and second piezoelectric pressure signals 29, 30, using the first and/or second methods described hereinbefore. The pressure values 32 a, 32 b may be output via the link 46.

As mentioned hereinbefore, the controller 25 provides the driving signal 39, V_(sig)(t) to each amplifier 34 of the first amplifier module 41 a. An input of each amplifier 34 of the first amplification module 41 a may be used to drive the corresponding first sensing electrode 14 of the first touch panel 10 using the driving signal 39, V_(sig)(t). Based on the driving signal 39, V_(sig)(t) and the first and second digitised amplified signals 50 a, 50 b obtained by the controller 25, the controller 25 calculates capacitance values 27 and/or touch data 31 based on the mutual-capacitance between the addressed first and second sensing electrodes 14, 20. The capacitance values 27 and/or touch data 31 may be output via the link 46.

Referring also to FIG. 15, an example of one configuration of charge amplifiers 34 a, 34 b, 44 suitable for use in the second apparatus is shown.

In one configuration, each charge amplifier 34 a, 34 b, 44 includes an operational amplifier OP having an inverting input, a non-inverting input and an output.

For example, each charge amplifier 34 a forming part of the first amplifier module 4 a includes an operational amplifier OP having an inverting input for coupling to a corresponding first sensing electrode 14 via an input resistance R_(i) and a first switch SW1 connected in series. The non-inverting input of the operational amplifier OP is connected to the driving signal 39, V_(sig)(t). The driving signal 39, V_(sig)(t) may be provided by the controller 25, by a separate module (not shown) of the second apparatus 37 or may be received into the second apparatus 37 from an external source. Since the inverting input will be at practically the same voltage as the non-inverting input, the inverting input can be caused to drive the corresponding first sensing electrode 14. A feedback network of the charge amplifier 34 a includes a feedback resistance R₆, a feedback capacitance C_(f) and a second switch SW2 connected in parallel between the inverting input and the output of the operational amplifier OP. The output of the operational amplifier OP provides the amplified signal 47 a.

Each charge amplifier 34 b forming part of the second amplifier module 41 b is the same as each charge amplifier 34 a of the first amplifier module 41 a, except that the non-inverting input of the operational amplifier OP is coupled to a common mode voltage V_(CM) instead of the driving signal 39, V_(sig)(t), and in that the inverting input is connected to a second sensing electrode 20 instead of a first sensing electrode 14.

The common electrode charge amplifier 44 is the same as the charge amplifiers 34 b forming part of the second amplifier module 41 b, except that the inverting input of the common electrode charge amplifier 44 is connected to the common electrode 15 and the common electrode charge amplifier 44 omits the first switch SW1.

Other terminals of the operational amplifiers OP, such as power supply terminals, may be present, but are not shown in this or other schematic circuit diagrams described herein.

The second switches SW2 permit the corresponding feedback capacitors C_(f) to be discharged. The opening and closing of the second switches SW2 may be governed by the second synchronisation signal Si provided by the controller 25. In this way, the feedback capacitors C_(f) of each charge amplifier 34 a, 34 b may be periodically discharged in order to reset the feedback network of the operational amplifier OP to prevent excessive drift. Optionally, the second switch SW2 of the common electrode charge amplifier 44 may also be synchronised using the second synchronisation signal 51.

The first switches SW1 may be controlled by the second synchronisation signal 51 provided by the controller 25 to enable an amplifier 34 a, 34 b to be connected or disconnected from the corresponding sensing electrode 14, 20 if required.

The first sensing electrodes 14 need not be transmitting, Tx electrodes and the second sensing electrodes 20 receiving, Rx electrodes. Alternatively, the controller 25 may provide the driving signal 39, V_(sig)(t) to the second amplifier module 41 b so that the second sensing electrodes 20 are transmitting, Tx electrodes and the received signals V_(meas)(t) are detected using the first sensing electrodes 14.

In other examples, the second apparatus 37 need not be configured for mutual capacitance measurements, and may instead be configured to measure self-capacitances of each first and second sensing electrode 14, 20. In this case, a self-capacitance measurement signal (not shown) may be provided to both the first and second amplifier modules 41 a, 41 b.

Second Touch Panel:

In the first touch panel 10, the first and second sensing electrodes 14, 20 have been shown in the form of elongated rectangular electrodes. However, other shapes may be used.

Referring also to FIG. 16, a second touch panel 53 having an alternative geometry of the first and second sensing electrodes 14, 20 is shown.

Instead of being rectangular, each first sensing electrode 14 may include several pad segments 54 evenly spaced in the first direction x and connected to one another in the first direction x by relatively narrow bridging segments 55. Similarly each second sensing electrode 20 may comprise several pad segments 56 evenly spaced in the second direction y and connected to one another in the second direction y by relatively narrow bridging segments 57. The pad segments 54 of the first sensing electrodes 14 are diamonds having a first width W1 in the second direction y and the bridging segments 55 of the first sensing electrodes 14 have a second width W2 in the second direction y. The pad segments 56 and bridging segments 57 of the second sensing electrodes 20 have the same respective shapes and widths W1, W2 as the first sensing electrodes 14.

The first and second sensing electrodes 14, 20 are arranged such that the bridging segments 57 of the second sensing electrodes 20 overlie the bridging segments 55 of the first sensing electrodes 14. Alternatively, the first and second sensing electrodes 14, 20 may be arranged such that the pad segments 56 of the second sensing electrodes 20 overlie the pad segments 54 of the first sensing electrodes 14. The pad segments 54, 56 need not be diamond shaped, and may instead be circular. The pad segments 54, 56 may be a regular polygon such as a triangle, square, pentagon or hexagon. The pad segments 54, 56 may be I shaped or Z shaped.

The alternative geometry of the second touch panel 53 is equally applicable in combination with the first or second apparatus 22, 37.

Third Touch Panel:

Referring also FIG. 17, a third touch panel 58 may be used in combination with the first or second apparatus 22, 37.

The third touch panel 58 is substantially the same as the first touch panel 10 except that the third touch panel 58 does not include the second layer structure 17 and the second sensing electrodes 20 are disposed on the first face 12 of the first layer structure 11 in addition to the first sensing electrodes 14. Each first sensing electrode 14 is a continuous conductive region extending in the first direction x. For example, each first sensing electrode 14 may include several pad segments 59 evenly spaced in the first direction x and connected to one another in the first direction x by relatively narrow bridging segments 60. Each second sensing electrode 20 may comprise several pad segments 61 evenly spaced in the second direction y. However, the pad segments 61 of the second sensing electrodes 20 are disposed on the first face 12 of the first layer structure 11 and are interspersed with, and separated by, the first sensing electrodes 14. The pad segments 61 corresponding to each second sensing electrode 20 are connected together by conductive jumpers 62. The jumpers 62 each span a part of a first sensing electrode 14 and the jumpers 62 are insulated from the first sensing electrodes 14 by a thin layer of dielectric material (not shown) which may be localised to the area around the intersection of the jumper 62 and the first sensing electrode 14.

Alternatively, a thin dielectric layer (not shown) may overlie the first face 12 of the first layer structure 11, the first sensing electrodes 14 and the conductive pads 61 of the second sensing electrodes 20. Conductive traces (not shown) extending in the second direction y may be disposed over the dielectric layer (not shown), each conductive trace (not shown) overlying the pad segments 61 making up one second sensing electrode 20. The overlying conductive traces (not shown) may connect the pad segments 61 making up each second sensing electrode 20 using vias (not shown) formed through the thin dielectric layer (not shown).

Modifications

It will be appreciated that many modifications may be made to the embodiments hereinbefore described. Such modifications may involve equivalent and other features which are already known in the design, manufacture and use of pressure and/or projected capacitance sensing touch panels and which may be used instead of or in addition to features already described herein. Features of one embodiment may be replaced or supplemented by features of another embodiment.

Third Apparatus:

Referring also to FIG. 18, a third apparatus 66 includes the first touch panel 10 and a second controller 67 for combined pressure and capacitance sensing.

The second controller 67 is the same as the first controller 40, except that in the second controller 67 the input signals from a first sensing electrode 14 are connected to a single charge amplifier 34 a by a first multiplexer 42 a. The charge amplifier 34 a outputs the first amplified signal 47 a, which is processed by the first primary ADC 38 a, the first secondary ADC 43 a and the controller 25 in the same way as for the first controller 40. Similarly, the input signals from a second sensing electrode 20 are connected to a single charge amplifier 34 b by a second multiplexer 42 b. The charge amplifier 34 b outputs the second amplified signal 47 b, which is processed by the second primary ADC 38 b, the second secondary ADC 43 b and the controller 25 in the same way as for the first controller 40. The acquisition and processing of signals from the common electrode 15 is the same as for the second apparatus 37.

In the same way as the first controller 40, use of primary and secondary ADCs 38, 43 is not essential. Instead, a single ADC (not shown) which is capable of alternating operation at the piezoelectric and capacitive sampling frequencies f_(piezo), f_(cap), so as to obtain the signals 49, 50 sequentially.

Although the examples described hereinbefore have been primarily described with reference to combined piezoelectric and capacitive touch panels and apparatus, it should be appreciated that the first and second methods of the specification may also be used in a touch panel apparatus which does not measure capacitances and which only measures piezoelectric pressure signals. Provided that a piezoelectric touch panel allows determining the coordinates x, y of a user interaction, appropriate pre-calibrated values of the coefficients k_(n)(x,y), h_(m)(x,y), and/or C_(CE)(x,y) may be retrieved and applied Equations (13), (15), (16), or the voltage equivalents thereof.

Although in the examples described hereinbefore a first piezoelectric pressure signal 29 is generated corresponding to each first or second sensing electrode 14, 20, this need not be the case. In other examples, signals from a group of two or more adjacent sensing electrodes 14, 20 may be combined by a single charge amplifier 34, to produce a first piezoelectric pressure signal 29 corresponding to the charge induced on the group of two or more adjacent sensing electrodes 14, 20.

Although the examples described hereinbefore have been primarily described with reference to touch panels in which first and second sensing electrodes 14, 20 are elongated in perpendicular directions, this need not be the case. In other examples, the second sensing electrodes 20 may be omitted and the first sensing electrodes may take the form of a two dimensional array of discrete touch panels. The first and second methods of the present specification may still be used with such examples.

Although claims have been formulated in this application to particular combinations of features, it should be understood that the scope of the disclosure of the present invention also includes any novel features or any novel combination of features disclosed herein either explicitly or implicitly or any generalization thereof, whether or not it relates to the same invention as presently claimed in any claim and whether or not it mitigates any or all of the same technical problems as does the present invention. The applicant hereby gives notice that new claims may be formulated to such features and/or combinations of such features during the prosecution of the present application or of any further application derived therefrom. 

What is claimed is:
 1. An apparatus for processing signals from a touch panel, the touch panel comprising a layer of piezoelectric material disposed between a plurality of sensing electrodes and at least one common electrode, the apparatus comprising: a first circuit for connection to the plurality of sensing electrodes and configured to generate a plurality of first pressure signals, wherein each first pressure signal corresponds to one or more sensing electrodes and is indicative of a pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes; a second circuit for connection to the at least one common electrode and configured to generate a second pressure signal indicative of a total pressure applied to the touch panel; and a controller configured to determine an estimate of the total pressure based on a weighted difference of the second pressure signal and a sum over the plurality of first pressure signals.
 2. The apparatus according to claim 1, wherein the controller is further configured to determine a location at which pressure is applied to the touch panel; wherein a coefficient used for the weighted difference of the second pressure signal and the sum over the plurality of first pressure signals depends upon the location.
 3. The apparatus according to claim 1, wherein the controller determines the estimate of the total pressure using the equation: F _(CE)=(1−C _(CE))Q _(CE) −C _(CE) Q _(sen) in which F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(CE) is a charge measured on the at least one common electrode, Q_(sen) is the sum of charges measured on all of the plurality of sensing electrodes, and C_(CE) is a pre-calibrated constant having a value between zero and unity; wherein the estimate of the total pressure is based on F_(CE).
 4. The apparatus according to claim 1, wherein the controller is further configured to determine, for each of at least one first pressure signal, an estimate of the pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes, based on the first pressure signal, the second pressure signal and the total pressure.
 5. The apparatus according to claim 4, wherein the controller is configured to determine a location at which pressure is applied to the touch panel; wherein one or more coefficients used to determine the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes depends upon the location.
 6. The apparatus according to claim 4, wherein the touch panel comprises a number N of sensing electrodes, and wherein the controller determines the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes using the equation: $F_{n} = {Q_{n} - {\frac{k_{n}}{C_{CE}}\left( {Q_{CE} - F_{CE}} \right)}}$ in which F_(n) is a piezoelectric charge induced on the n^(th) of N sensing electrodes, F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(n) is a charge measured on the n^(th) of N sensing electrodes, Q_(CE) is a charge measured on the at least one common electrode, C_(CE) is a pre-calibrated constant having a value between zero and unity, and k_(n) is a pre-calibrated constant corresponding to the n^(th) of N sensing electrodes and having a value between zero and unity; wherein the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes is based on one or more corresponding values of F_(n).
 7. The apparatus according to claim 1, wherein the first circuit is configured to generate, for each sensing electrode, a capacitance signal indicative of a capacitance of the sensing electrode; wherein the controller is configured to determine a location at which pressure is applied to the touch panel based on the capacitance signals.
 8. The apparatus according to claim 7, wherein generating the first pressure signals and the capacitance signals comprises separating single signals received from the sensing electrodes.
 9. A touch panel system comprising: a touch panel comprising a layer of piezoelectric material disposed between a plurality of sensing electrodes and at least one common electrode; and, an apparatus for processing signals from the touch panel, the apparatus comprising: a first circuit for connection to the plurality of sensing electrodes and configured to generate a plurality of first pressure signals, wherein each first pressure signal corresponds to one or more sensing electrodes and is indicative of a pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes; a second circuit for connection to the at least one common electrode and configured to generate a second pressure signal indicative of a total pressure applied to the touch panel; and a controller configured to determine an estimate of the total pressure based on a weighted difference of the second pressure signal and a sum over the plurality of first pressure signals.
 10. An electronic device comprising a touch panel system according to claim
 9. 11. A method of processing signals from a touch panel, the touch panel comprising a layer of piezoelectric material disposed between a plurality of sensing electrodes and at least one common electrode, the method comprising: generating a plurality of first pressure signals, each first pressure signal based on signals received from one or more sensing electrodes, and each first pressure signal indicative of a pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes; generating, based on signals received from the at least one common electrode, a second pressure signal indicative of a total pressure applied to the touch panel; and determining an estimate of the total pressure based on a weighted difference of the second pressure signal and a sum over the plurality of first pressure signals.
 12. The method according to claim 11, further comprising determining a location at which pressure is applied to the touch panel; wherein a coefficient used for the weighted difference of the second pressure signal and the sum over the plurality of first pressure signals depends upon the location.
 13. The method according to claim 11, wherein determining the estimate of the total pressure applied to the touch panel comprises using the equation: F _(CE)=(1−C _(CE))Q _(CE) −C _(CE) Q _(sen) in which F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(CE) is a charge measured on the at least one common electrode, Q_(sen) is the sum of charges measured on all of the plurality of sensing electrodes and C_(CE) is a pre-calibrated constant having a value between zero and unity; wherein the estimate of the total pressure is based on F_(CE).
 14. The method according to claim 11, further comprising determining, for each of at least one first pressure signal, an estimate of the pressure acting on the touch panel proximate to the corresponding one or more sensing electrodes, based on the first pressure signal, the second pressure signal and the total pressure.
 15. The method according to claim 14, comprising determining a location at which pressure is applied to the touch panel; wherein one or more coefficients used to determine the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes depends upon the location.
 16. The method according to claim 14, wherein the touch panel comprises a number N of sensing electrodes, and wherein determining the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes comprises using the equation: $F_{n} = {Q_{n} - {\frac{k_{n}}{C_{CE}}\left( {Q_{CE} - F_{CE}} \right)}}$ in which F_(n) is a piezoelectric charge induced on the n^(th) of N sensing electrodes, F_(CE) is a piezoelectric charge induced on the at least one common electrode, Q_(n) is a charge measured on the n^(th) of N sensing electrodes, Q_(CE) is a charge measured on the at least one common electrode, C_(CE) is a pre-calibrated constant having a value between zero and unity, and k_(n) is a pre-calibrated constant corresponding to the n^(th) of N sensing electrodes and having a value between zero and unity; wherein the estimate of the pressure acting on the touch panel proximate to the one or more sensing electrodes is based on one or more corresponding values of F_(n).
 17. The method according to claim 11, comprising generating, based on signals received from each sensing electrode, a capacitance signal indicative of a capacitance of the sensing electrode; the method further comprising determining a location at which pressure is applied to the touch panel based on the capacitance signals.
 18. The method according to claim 17, wherein generating the first pressure signals and the capacitance signals comprises separating single signals received from the sensing electrodes. 